EP0563111A1

EP0563111A1 - A method for the preparation of a polymerizing catalyst component, a polymerizing catalyst component prepared by the method and its use.

Info

Publication number: EP0563111A1
Application number: EP92900911A
Authority: EP
Inventors: Bill Gustafsson; Arja Kostiainen; Pekka Sormunen
Original assignee: Neste Oyj
Current assignee: Borealis AS
Priority date: 1990-12-19
Filing date: 1991-12-17
Publication date: 1993-10-06
Anticipated expiration: 2011-12-17
Also published as: FI906281A; FI86989B; DE69125847D1; US5480849A; DE69125847T2; EP0563111B1; FI906281A0; FI86989C; CA2098380A1; WO1992011296A1

Abstract

L'invention se rapporte à un procédé qui sert à préparer une composition pro-catalytique solide pour système de catalyseur en vue d'assurer la polymérisation des oléfines et dans lequel un halogénure de magnésium, tel que du chlorure de magnésium, est dissous et/ou mis en suspension dans un ester alkyle d'un acide monocarboxylique, tel que de l'acétate d'éthyle, imprégné sur un support, traité avec un composé organométallique ou un composé de silicium puis avec un composé métallique de transition. L'invention se rapporte également à une composition pro-catalytique et à son utilisation avec un co-catalyseur en vue d'assurer la polymérisation des oléfines. L'activité d'un tel système de catalyseur est améliorée dans la présente invention grâce à l'utilisation d'un support contenant des groupes hydroxyle et maintenu à une température d'environ 200 °C au maximum avant l'étape d'imprégnation, de sorte que les groupes hydroxyle soient retenus dans le support en quantité importante jusqu'à l'étape d'imprégnation. Le support est de préférence constitué par de la silice traitée thermiquement à 100-200 °C, pour que l'eau présente soit éliminée mais pour que les groupes hydroxyle soient retenus en quantité considérable. Le composé organométallique est de préférence un composé d'aluminium-alkyle, par exemple du triéthylaluminium, et le composé métallique de transition est de préférence du tétrachlorure de titane.The invention relates to a method for preparing a solid pro-catalyst composition for a catalyst system for the polymerization of olefins and in which a magnesium halide, such as magnesium chloride, is dissolved and/ or suspended in an alkyl ester of a monocarboxylic acid, such as ethyl acetate, impregnated on a support, treated with an organometallic compound or a silicon compound and then with a transition metal compound. The invention also relates to a pro-catalytic composition and to its use with a co-catalyst with a view to ensuring the polymerization of olefins. The activity of such a catalyst system is improved in the present invention thanks to the use of a support containing hydroxyl groups and maintained at a temperature of approximately 200° C. at most before the impregnation step, so that the hydroxyl groups are retained in the support in significant quantity until the step of impregnation. The support is preferably constituted by silica heat-treated at 100-200° C., so that the water present is eliminated but so that the hydroxyl groups are retained in considerable quantity. The organometallic compound is preferably an aluminum-alkyl compound, for example triethylaluminum, and the transition metal compound is preferably titanium tetrachloride.

Description

A method for the preparation of a polymerizing catalyst component, a polymerizing catalyst component prepared by the method and its use

The present invention relates to method for the preparation of a solid procatalyst composition of a catalyst system for the polymerizing olefins wherein the carrier is impregnated with a magnesium halide and a monoσarboxylic acid alkyl ester solubilizing it, and the impregnated carrier is reacted with an organometallic compound or a silicon compound and treated with a transition metal compound.

In the polymerization od olefins a so called Ziegler-Natta- catalyst system usually is used consisting of a so called procatalyst and a co-catalyst. The procatalyst is based on a compound of a transition metal belonging to some of the groups IVB-VIII of the periodic system of the elements and the co-catalyst is based on an organometallic compound of a metal belonging to some of the groups IA-IIIA of the perio¬ dic system of the elements.

It is conventional to use in the preparation of heterogenic polymerization catalysts as a component enhancing the poly- merization activity of the proσatalysts a support carrier on which the transition metal compound is superposed. Usual carriers are silica, aluminum oxide, magnesium oxide, titanium oxide, carbon in different forms an different polymer types. As important carriers have proved the magnesium compounds such as alkoxides, hydroxides, hydroxy halides and halides, of which the latter, in particular magnesium dichloride, have recently become the most significant carrier components of procatalyst compositions.

Because magnesium halides are in their base crystal form not activated very efficiently with a transition metal compound, their crystal form has to be deformed. Traditionally this is carried out by grinding e.g. in a ball mill typically resulting in a finely divided powder with a large specific surface the particles of which have a strongly deformed crystal lattices. When such a powder is activated to a procatalyst composition by superposing on it a transition metal compound, and there after reduced with an organometallic compound as a co-catalyst, a very active polymerizing catalyst is obtained.

Drawbacks of the usual method for grinding magnesium halide include, anyhow, that it is very energy consuming, causes wearing and corrosion of the apparatus and is suited to the production of catalyst only with the tedious batch process.

A more modern method to lessen the crystallinity of the magnesium halide and thereby enhance its ability to become activated with a transition metal compound is to modify them chemically. Thereby a magnesium halide, an electron donor and a transition metal compound are reacted with each other, often in a solution, to an easily isolated procatalyst compositions.

The U.S. Patents 4,124,532 and 4,174,429 describe the preparation of this kind of catalytically active complexes by reacting a magnesium halide and a transition metal compound at a suitable ratio in a electron donor solvent. The finished complex can be separated through a crystallization by evaporation of the said solvent or by mixing the complex with a solvent in which is not soluble. Because such complex compounds are formed as a result of a spontaneous crystallization, their crystal structure is very regular and activity correspondingly rather limited.

U.S. Patent 4,302,566 and EP Patent Application 6,110 describe a precursor formed by a magnesium halide, a transition metal compound and an electron donor. The precursor is formed by precipitation from an electron donor solution whereafter it is separated and mixed with an aluminumalkyl and a separate inert carrier.

In these methods processes an essentially amorphous procatalyst composition is not formed either, because the precursor in question is crystallized in the preparation spontaneously and its morphology is not essentially changed after that.

Other patents describe Ziegler-Natta procatalysts on a silica or magnesium silicate carrier but they are not taking advantage of the superior ability of the magnesium compounds to activate transition metals. Such patents include e.g.: WO-8,802,376, EP-215,916, EP-120,503, EP-91,135, EP-80,052, EP-55,605, EP-43,220, EP-20818, US-4,482,687, US-4,383,095, US-4,354,009, US-4,349,648 and US-4,359,561.

U.S. Patent 4,670,526 describes a process for the activation of a catalyst wherein a divalent magnesium halide together with a Lewis acid, e.g. an ethyl aluminum chloride, is dissolved in an excess of an electron donor, and the complex obtained is separated from the excess of electron donor before the treatment with a titanium or a vanadium compound. The complex is alternatively also superposed on silica.

EP Patent Application 267,794A2 describes a catalyst system which is prepared by combining silica or alum with a magnesium halide and an organometallic compound. The combining is typically carried out by dissolving the magnesium halide in an inert solvent, of which solvents ethyl acetate also is mentioned. About silica it is mentioned that it can contain minor amounts of water although in the silica is calcinated in the performing examples. Before the treatment with a transition metal compound the catalyst component is according to the performing examples treated with an electron donor, e.g. vinyl ethoxy silane and triphenyl phosphite, presumably in order to enhance the isotacticity of the polypropylene polymerizable with the catalyst.

The present invention has as an object to provide a method for the preparation of a procatalyst composition consisting of a carrier, a magnesium halide, an organometallic or a silicon compound and a transition metal compound which procatalyst composition is structurally as amorphous as possible and hence catalytically as active as possible, which method is easier than the prior art methods. The invention also has as an object a method for the preparation of a solid catalyst system for the polymerization of olefins wherein a separate step for grinding of the magnesium halide is not needed and the treatment with a transition metal compound is carried out in so late step of preparation that in its complexing no more recrystallization or loss of activity of the product is taking place. The invention also has as an object to find as appropriate use for the novel procatalyst composition as possible in the polymerization or copolymerization of olefins and especially α-olefins.

These objects have been fulfilled according to the invention by the use of a carrier containing hydroxyl groups, which carrier is kept prior to the impregnation at a temperature of at most about 200°C so that the hydroxyl groups are retained in the carrier to an essential extent until the impregnating step.

The invention hence resides in that the change of the morphology of the magnesium halide required for the activity is provided by impregnating a separate inert inactivated hydroxyl-containing carrier with the magnesium halide and a monoσarboxylic acid alkyl ester dissolving it. When the impregnated carrier is then reacted with an organometallic compound such as an organometallic compound of a metal belonging to some of the groups IA-IIIA, preferably an aluminumalkyl compound or a silicon compound, preferably halide or alkyl halide compound in order to remove excess of water, as a result a solid carrier coated with a magnesium halide is obtained from which also the hydroxyl groups impairing the catalytic properties have been removed.

Essential for the invention is hence that the removal of the hydroxyl groups of the carrier is taking place simultaneously with the removal of the excess of the solvent ester wherein the separate activation of the carrier before the impregnation step is avoided. By the activation herein is meant a treatment wherein the surface hydroxyl groups bound to the carrier are removed by a chemical and/or thermal treatment. The removal of to the carrier solely physisorbed water is not here considered to be activation. Such an activating step is in an industrial scale from the investment point of view an expensive and time consuming process while it has in general to be carried out by fluidizing the carrier at a temperature over 300°C. In general in addition to this thermal activation, calcination it has been advantageous to remove all the remaining hydroxyl groups with a chemical treatment, e.g. with an organoaluminum compound or a silicon compound.

Finally the carrier treated as mentioned is manipulated with a transition metal compound such as titanium tetrachloride. One of the useful characters of the invention is that the treatment with the transition metal compound is taking place later than in the conventional homogenous activations of a procatalyst composition whereby the recrystallization of the procatalyst composition is avoided and the activity of the mixture is hence retained.

The preparation of the solid procatalyst composition of a catalyst system for the polymerization of olefins hence begins with dissolving or suspending anhydrous magnesium halide to a suitable monocarboxylie acid alkyl ester as a solvent. With the used magnesium halide especially magnesium halide is mentioned wherein chlorine, bromine, iodine or a mixture of them is as a halide. The most preferable magnesium halide is anhydrous and dry magnesium dichloride MgCl₂. The ester used as a solvent is a liquid in the process conditions, in which solvent the magnesium compound is partly or preferably totally soluble. It is preferably an alkyl ester of a carboxylic acid containing 1-10 carbon atoms and quite especially ethyl acetate. The dissolving of the magnesium halide is carried out, if needed, by mixing at an elevated temperature.

In the following step a separate hydroxyl-containing carrier is impregnated with the obtained solution or suspension of magnesium halide. An alternative method for superposing magnesium halide on a carrier is to add the magnesium halide and the solvent concurrently with the carrier to form a suspension from which the magnesium halide after have been dissolved is at least essentially superposed on the carrier surface.

The inert carrier is preferably an inorganic oxide of silicon, silica, although some other inorganic hydroxyl- containing oxides such as Mg, Al and Ti oxides and/or salts such as magnesium silicate can come into question. The particle size of silica is 10-200 μm, preferably 40-150 μm. It is preferably chosen to give as narrow particle size distribution as possible. In addition these carriers are porous and their area is preferably over 100 m²/g and pore volume greater than 1 cmVg. The untreated silica is containing water which is removed with a thermal treatment, e.g. 100-200°C, preferably 150-200°C, or for instance by distilling water azeotropically with aid of heptane. Although the water present in the silica is removed, the silica is still containing a lot of hydroxyl groups. In the known methods this has been removed with different ways, ie. by warming in an.oven, in a stream of nitrogen or in atmosphere to a temperature of at least 200°C and usually about 600°C, or by chemical methods.

In the present invention it has been found out that when a hydroxyl-containing carrier is used the hydroxyl groups of which have essentially been retained until the impregnation step, the disadvantageous features of the drying in an oven, calcination and chemical treatment are avoided and at the same time better results are obtained in respect of the properties of the catalyst. The most essential profit is that the process is getting more simple because as the only measure the carrier can require the removal of the water present at a temperature of about 100-200°C, preferably 150- 200^βC.

The removal of water which is carried before the impregnation can be carried out by warming the carrier to a temperature of 100-200°C, preferably with aid of a stream of gas, e.g. nitrogen. In laboratory scale this step can be carried out practically also in a separate oven because when small quantities of material and low temperatures are in question this can be carried out with very simple apparatus. An other way to remove water is to distill the water azeotropically e.g. with the aid of heptane. This is preferable especially with large amounts of material.

When the hydroxyl-containing carrier has been impregnated with a magnesium halide solution or suspension which is carried, if needed, at an elevated temperature, the solvents are evaporated off and the impregnated carrier is then reacted by treating it with an organometallic compound of a metal belonging to some of the groups IA-IIIA, preferably with an aluminumalkyl compound or a silicon compound, preferably a chloride or an alkylchloride. Following this treatment the product obtained can be washed in order to remove the dissolved reaction products, but the washing is not necessary. The treatment with the transition metal compound is preferably carried out by preparing from the above mentioned impregnated and dried carrier particles a hydrocarbon suspension in which the transition metal is added, or by adding it directly to the solution from the previous treatment. This treatment can be accelerated by the use of mixing and an elevated temperature. The transition metal compound is preferably a halide compound containing titanium, vanadium and/or zirconium. Especially preferable are the titanium compounds and the most preferable is titanium tetrachloride TiCl₄.

The procatalyst composition obtained after the transition metal compound is dried and analyzed. The washing steps are not necessary; good results have been obtained although the solvent has only been evaporated or the procatalyst is remaining as a suspension. The treatment with an organometal or silicon compound and the treatment with a transition metal can also be carried out using a so called dry-mixing without suspending into an excess of a hydrocarbon solvent.

From the tests carried out in connection of the invention it was surprisingly found out that the performance of the catalyst prepared by the described method was excellent and that it suited especially well for the polymerization of ethylene with a high activity and good hydrogen sensitivity although the tedious carrier activation step preceding the impregnation could be avoided. The polymer obtained had a narrow molecular weight distribution (MWD) and good morphology for various uses. The specific advance of this invention compared to FI Patent Application 891313 is the enhanced activity expressly with aid of the chemical removal of the excess of electron donor and to FI Patent Application 895526 the essentially easier method for the preparation of the catalyst; we have e.g. surprisingly found out that from the production steps of the catalyst in particular the time consuming and tedious steps in view of the process can be avoided wherein the additional siphonations and filterings can be excluded (cf. Examples 2 and 3).

Examples Separate carriers

When as the separate carrier silica is used, it is first treated simply e.g. in the same reaction vessel or separately for some hours with a mild heating at 150-200°C without the presence of solvents.

In the following examples silica (Davison 955) has been kept for 4 hours at a temperature of 150°C in a glass pipe leading nitrogen through the pipe.

Example la

15 grams of silica which had been dried by the above mentioned method was added to a 500-mL reactor. Meanwhile in an other flask a solution of MgCl₂ in ethyl acetate (EA) was prepared by dissolving 4.5 grams of MgCl₂ into 200mL of dried ethyl acetate at a temperature of 70°C mixing for 2 hours.

This solution was conducted onto the silica, mixed for 1 hour at a temperature of 80°C and dried. 19.1 grams of a product was obtained containing 5.7% of Mg and 13.2% of EA.

Example lb

2.5 grams of silica which had been dried by the above mentioned method was treated according to Example la now using 0.75 grams of MgCl₂ and 33mL of EA.

Example 2

3,5 grams of the impregnated carrier (containing Mg 0.008 moles, EA 0.005 moles, Si0₂, estimated OH-content 5.67 mmoles) prepared in Example 1 was suspended into pentane. To this was added slowly at room temperature 19mL of a 10% wt. solution of triethylaluminum (TEA) in pentane (0.011 moles, Al/(EA+0H) = 1:1). The temperature was raised to the boiling point of pentane and kept at this temperature for 40 minutes. Next the reaction product thus obtained was washed with pentane and heptane. The washed reaction product was resuspended into heptane and 9mL of TiCl₄ (0.003 moles) was added and mixed at a temperature of 60°C for 4 hours. The procatalyst obtained was weighed after washings and drying, yield 3.2 grams. It contained 4.3% of Mg, 1,6% of Al, 4.6% of Ti and 4.0% of EA. The polymerization results are presented in Table 1.

Example 3

3,5 grams of the carrier prepared in Example 1 was treated by the method explained in Example 2 using now also 19 ml of a 10% wt. solution of TEA in pentane. Thereafter a titanation was carrier out using this time only 0.9mL of TiCl₄; temperature 60^βC for 4 hours. The obtained reaction product was not washed but just dried. Yield 1.53 grams. The procatalyst composition contained 4.1% of Mg and 5.1% of Ti, 1.7% of Al and 3.9% of EA.

Example 4

As previous Example but now using only 0.3mL of TiCl₄. Yield 3.0 grams of a procatalyst composition containing 4.7% of Mg, 3.2% of Ti, 1.9% of Al and 3.5% of EA.

Example 5

2.5 grams of the carrier prepared in Example 1 was suspended into lOmL of heptane, 6.5mL of a 10% wt. solution of TEA in pentane was added and mixed for 2 hours at a temperature of 40°C. After drying (without washing) the obtained reaction product was resuspended into heptane, 0.2 mL of TiCl₄ was added and mixed for 2 hours at a temperature of 60°C. Finally the procatalyst was dried, yield 1.4 grams. The procatalyst composition contained 3.6% of Mg, 3.6% of Al, 5.1% of Ti and 6.8% of EA. Although the ethyl acetate remainder without washings is higher than usually the performance of the catalyst is still good (Table 1).

Example 6

As previous Example but now using lO L of the TEA solution. 2.75 grams of a procatalyst composition was obtained containing 3.4% of Mg, 3.3% of Al, 4.9% of Ti and 4.1% of EA.

Example 7 As Example 5 but now the MgCl₂-silica carrier was not dried after the TEA treatment but the excess of solution was siphonated off, the carrier was suspended into heptane and titanated. The obtained procatalyst composition contained: 4.0% of Mg, 2.7% of Ti, 2.3% of Al and 5.8 % of EA.

Example 8

This example shows that an acceptable catalyst can also be produced without suspending the solid materials into an excess of hydrocarbon solvent using a so called dry-mixing technique.

3.6 grams of the carrier prepared in Example lb was mixed with 9.6mL of a 10% solution of TEA for 1 hour at a temperature of 40°C. After drying the mixing was continued for further 3 hours at the same temperature. To the dry carrier mixture 0.28mL of TiCl₄ was added and the dry powder was mixed for 16 hours also at a temperature of 40°C and finally further at a temperature of 60°C for 1.5 hours. 3.26 grams of a procatalyst composition was obtained containing 4.0% of Mg, 3.9% of Al, 4.8% of Ti and 9.4% of EA.

Test polymerization

The test polymerization of ethylene was carried out in each of the Examples by the following method: a 3-L autoclave was loaded with 1.8L of isobutane which had been purified with oxygen and moisture removers. 40-100 milligrams of the pro¬ catalyst composition was fed to the reactor with the aluminumalkyl (TEA, Al/Ti - 50-75). The temperature was raised to 90°C. A 0.5-L pressure vessel or bomb was pressurized to 5 bars with hydrogen and conducted together with ethylene to the reactor until the total pressure was 28 bars. The polymerization was carried out for 1 hour and the total pressure was kept constant with aid of the ethylene feed.

Table 1 Polymerization results

MI: melt index, ASTM D 1238, conditions 190^βC/21,6 kilograms and 2,16 kilograms

MFR: melt flow ratio, melt indices 21,6 kilograms and 2,16 kilograms

BD: bulk density, grams/mL

Claims

13Claims

1. A process for the preparation of a solid procatalyst composition of a catalyst system for the polymerization of olefins wherein the carrier is impregnated with a magnesium halide and an alkyl ester of a monocarboxylie acid dissolving it, and the impregnated carrier is reacted with an organometallic compound or a silicon compound and treated with a transition metal compound, characterized in that a hydroxyl-containing carrier is used which is kept prior to the impregnation at a temperature of at most about 200°C so that the hydroxyl groups are essentially retained in the carrier until the impregnation step.

2. A process according to claim 1, characterized in that the carrier is treated thermally at a temperature of about 100-

200°C wherein the water optionally present is removed from the carrier but an essential amount of hydroxyl groups is retained and that the treated hydroxyl-containing carrier is thereafter impregnated with a magnesium halide and the said alkyl ester.

3. A process according to claim 1 or 2, characterized in that as the carrier silica is used.

4. A process according to any of the previous claims, characterized in that the magnesium halide is dissolved or suspended to the ester used as the solvent and that the carrier is impregnated with the solution or suspension thus obtained.

5. A process according to any of the previous claims, characterized in that the magnesium halide is anhydrous magnesium chloride and that the alkyl ester of monocarboxylie acid used as the solvent is ethyl acetate.

6. A process according to any of the previous claims, characterized in that the impregnated carrier is reacted with an aluminumalkyl compound such as triethylaluminum and treated with a titaniumhalide compound such as titanium tetrachloride.

7. A solid procatalyst composition of a catalyst system for the polymerization of olefins prepared with a process according to any of the previous claims, characterized in that the composition has been produced by treating thermally a carrier containing hydroxyl groups at a temperature of at most 200°C, by impregnating the carrier wherein the hydroxyl groups are essentially retained with a magnesium halide and an alkyl ester of a monocarboxylic acid dissolving it and by reacting the impregnated carrier with an organometallic compound or a silicon compound and by treating it with a transition metal compound.

8. A composition according to claim 7, characterized in that as the carrier silica is used.

9. A composition according to claim 7 or 8, characterized in that the magnesium halide is magnesium chloride and that the ester used as the solvent is ethyl acetate.

10. A composition according to any of claims 7-9, characterized in that the impregnated carrier has been reacted with an aluminumalkyl compound such as triethyl¬ aluminum and treated with a titaniumhalide compound such as titanium tetrachloride.

11. The use of a procatalyst composition according to any of claims 7-10 of prepared according to any of the claims 1 - 6 together with an organometallic co-catalyst compound of aluminum and optionally an external donor for the polymerization and σopolymerization of α-olefins, especially ethylene.